2 research outputs found
Flexible or Robust Amorphous Photonic Crystals from Network-Forming Block Copolymers for Sensing Solvent Vapors
Large-area
and flexible amorphous photonic crystals (APCs) featuring
interconnected network microstructures are fabricated using high-molecular-weight
polystyrene-<i>block</i>-polyÂ(methyl methacrylate) (PS–PMMA)
block copolymers. Kinetically controlled microphase separation combining
with synergistic weak incompatibility gives rise to short-range-order
network microstructures, exhibiting noniridescent optical properties.
Solubility-dependent solvatochromism with distinct responses to various
organic solvent vapors is observed in the network-forming APC film.
By taking advantage of photodegradation of the PMMA block, nanoporous
network-forming films were prepared for subsequent template synthesis
of robust SiO<sub>2</sub>- and TiO<sub>2</sub>-based APC films through
sol–gel reaction. Consequently, refractive index contrast of
the APC film was able to be manipulated, resulting in intensely enhanced
reflectivity and increased response rate for detecting solvent vapor.
With the integration of self-assembly and photolithography approaches,
flexible and robust network-forming APC films with well-defined photopatterned
textures are carried out. This can provide a novel means for the design
of photopatterned organic or inorganic APC films for sensing solvent
vapors
Flexible or Robust Amorphous Photonic Crystals from Network-Forming Block Copolymers for Sensing Solvent Vapors
Large-area
and flexible amorphous photonic crystals (APCs) featuring
interconnected network microstructures are fabricated using high-molecular-weight
polystyrene-<i>block</i>-polyÂ(methyl methacrylate) (PS–PMMA)
block copolymers. Kinetically controlled microphase separation combining
with synergistic weak incompatibility gives rise to short-range-order
network microstructures, exhibiting noniridescent optical properties.
Solubility-dependent solvatochromism with distinct responses to various
organic solvent vapors is observed in the network-forming APC film.
By taking advantage of photodegradation of the PMMA block, nanoporous
network-forming films were prepared for subsequent template synthesis
of robust SiO<sub>2</sub>- and TiO<sub>2</sub>-based APC films through
sol–gel reaction. Consequently, refractive index contrast of
the APC film was able to be manipulated, resulting in intensely enhanced
reflectivity and increased response rate for detecting solvent vapor.
With the integration of self-assembly and photolithography approaches,
flexible and robust network-forming APC films with well-defined photopatterned
textures are carried out. This can provide a novel means for the design
of photopatterned organic or inorganic APC films for sensing solvent
vapors